KR101436978B1 - Simultaneous multiband operation of a mimo communication device - Google Patents

Abstract

Systems and methods are provided to support simultaneous connections to multiple network connections. For example, a wireless radio of a communication device may be used to transmit or receive data from two network channels, each associated with a network connection. The communication device allocates a first set of resources from the wireless radio to be used for communication over a first network channel and a second set of communication resources from the wireless radio to be used for simultaneous communication over a second network channel can do.

Description

[0001] SIMULTANEOUS MULTIBAND OPERATION OF A MIMO COMMUNICATION DEVICE [0002]

The present disclosure relates to wireless communications. More particularly, this disclosure relates to simultaneous multiband operation of a multiple-input-multiple-output ("MIMO") communication device.

Continuous development and rapid improvements in modern technology have resulted in widespread availability and use of mobile communication devices. Consumers continue to demand and purchase mobile devices with additional capabilities. As a result, mobile communication devices and component manufacturers continue to develop additional communication features for mobile communication devices, such as cellular telephones. There is a multi-input-multiple-output ("MIMO") technology as one of the communication technologies under development, and Korean Patent Application Publication No. 10-2010-0041662 (Apr.

This disclosure relates to the simultaneous multi-band operation of a multiple-input-multiple-output ("MIMO") communication device.

According to one aspect, a method is provided, the method comprising:

In a multiple-input-multiple-output ("MIMO") communication device comprising a wireless radio with multiple physical ("PHY") transceiver cores:

Alternately communicating in time division fashion across a first network channel and a second network channel using the plurality of PHY transceiver cores together;

Recognizing a transition indication to operate in a simultaneous multi-band communication mode,

In response:

Assigning a first PHY transceiver core from the plurality of PHY transceiver cores to communicate over the first network channel;

Assigning a second PHY transceiver core from the plurality of PHY transceiver cores to communicate over the second network channel; And

And communicating data over the first network channel using the first PHY transceiver core while simultaneously communicating data over the second network channel using the second PHY transceiver core.

Advantageously, said first PHY transceiver core is different from said second PHY transceiver core.

Advantageously, the method further comprises the step of identifying a transition condition to switch operation to the simultaneous operation mode.

Preferably, the first set of PHY transceiver cores include a single PHY transceiver core and the second set of PHY transceiver cores include a single PHY transceiver core.

Advantageously, the method comprises:

Receiving a switching indication to operate in a single band communication mode; And

And communicating data over a network channel using the plurality of PHY transceiver cores.

Advantageously, the method comprises:

Further comprising replicating a medium access control ("MAC") related architecture to support communicating data across the plurality of network channels.

Preferably, the step of replicating the MAC-related architecture comprises replicating the MAC-related architecture virtually.

According to one aspect, a communication device comprises:

A first PHY core operable to communicate across multiple network channels;

A second PHY core operable to communicate across multiple network channels; And

A communications controller communicatively coupled to the first PHY core and the second PHY core, the communications controller comprising:

A single-band communication mode in which the first PHY core and the second PHY communicate data over a network channel in a time division manner; And

And a multi-band communication mode in which the first PHY core communicates data over a first network channel while the second PHY core communicates data over a second network channel. The communication controller being operable to set a current communication mode of the second PHY.

Advantageously, said first network channel and said second network channel are associated with different network connections.

Advantageously, the first PHY core includes a register space that tracks the current communication mode of the first PHY core.

Advantageously, the second PHY core includes a register space that tracks the current communication mode of the second PHY core.

Advantageously, the multi-band communication mode comprises a medium access control ("MAC") related architecture that is replicated to support both the first and second PHY cores.

Preferably, the MAC architecture includes a virtual MAC related architecture.

Advantageously, the MAC-related architecture includes a data path between a host processor interface and a PHY interface, a direct-memory-access ("DMA") channel, an encryption engine, a time synchronization function timer, a first- ; "FIFO") queue, or any combination thereof.

According to one aspect, the method comprises:

 In a multiple-input-multiple-output ("MIMO") communication device comprising multiple physical ("PHY &

Performing MIMO communication over a first network channel associated with a first network connection using the plurality of PHY cores;

Receiving a request to communicate across a second network connection;

Allocating a first subset of the plurality of PHY cores to continue communication over the first network channel;

Assigning a second subset of the plurality of PHY cores to communicate over a second network channel associated with the second network connection, wherein the second subset of the plurality of PHY cores comprises a plurality of PHY cores Assigning a second subset of the plurality of PHY cores that does not include any PHY cores from the first subset; And

Communicating over the first network channel using the first subset of the plurality of PHY cores and communicating over the second network channel using the second subset of the plurality of PHY cores do.

Advantageously, the method comprises:

Assigning a first subset of the plurality of PHY cores to continue communication over the first network channel and sending a display message to a device communicatively coupled to the communication device via the first network connection Wherein the indication message further comprises transmitting the indication message indicating the first subset of the plurality of PHY cores allocated for communication across the first network connection.

Advantageously, said first subset of said plurality of PHY cores comprises a single PHY core.

Advantageously, said second subset of said plurality of PHY cores comprises a single PHY core.

Advantageously, the method comprises:

Receiving a request to communicate across a third network connection; And

And allocating a third subset of the plurality of PHY cores to communicate over a third network channel associated with the third network connection,

Wherein the third subset of the plurality of PHY cores is selected from the first subset of the plurality of PHY cores, the second subset of the plurality of PHY cores, the plurality of PHY cores, or any combination thereof Of PHY cores;

The third subset of the plurality of PHY cores does not include any PHY cores from the first subset of the plurality of PHY cores or the second subset of the plurality of PHY cores.

Advantageously, the method comprises:

Receiving an indication that communication over the second network connection is complete;

Allocating the second subset of the plurality of PHY cores to communicate over the first network channel; And

Performing MIMO communications across the first network channel using the first subset of the plurality of PHY cores and the second subset of the plurality of PHY cores.

According to the present invention, when operating in a simultaneous multi-band communication mode, the communication device can broadcast packets to both the first wireless network and the second wireless network even when the packet transmission time overlaps. Further, when operating in a simultaneous multi-band communication mode, the communication device may reduce the overhead required to continue to switch communication resources for subsequent communication over one network channel while operating in a single band communication mode .

The invention may be better understood with reference to the following drawings and description. In the drawings, like reference numerals designate corresponding parts throughout the different views.
1 shows a time multiplexed communication method.
2 shows a timing example of simultaneous multi-band communication.
Figure 3 shows another timing example of simultaneous multi-band communication.
4 shows an example of timing of simultaneous multi-band communication.
5 illustrates an example of a mobile communication device supporting simultaneous multi-band communication.
Figure 6 illustrates an example of concurrent multi-band logic that a communications device may implement in hardware, software, or both.
Figure 7 illustrates an example of a MAC related architecture in which a portion thereof may be replicated to support simultaneous multi-band communication.

The following discussion refers to a communication device. A communication device may take many different forms and may have many different functions. As one example, the communication device may be a cellular telephone capable of making and receiving wireless telephone calls. The communication device may also be a smartphone that drives general purpose applications besides making and receiving telephone calls. The communication device may further include a driver assistance module in a vehicle, an emergency transponder, a pager, a satellite television receiver, a networked stereo receiver, a computer system ), A music player, or any other device imaginable, as well as any other device that is wirelessly connected to the network. The following discussion deals with how a communication device can simultaneously communicate across multiple network channels using communication resources, such as wireless communication radios.

1 illustrates a time multiplexed communication method 100. As shown in FIG. The communication device 110 may include a wireless communication radio 120 that includes a transceiver 122 and a transceiver 124. [ Transceiver A 122 includes antenna A 126 and transceiver B includes antenna B 128. The transceiver (e.g., transceiver A 122 or transceiver B 124) may be a digital-to-analog (A / D) converter, Or any other hardware that drives an antenna (e.g., antenna A 126 or antenna B 128), may be used to implement the invention, . Transceiver A 122 may transmit or receive data via antenna A 126 and transceiver B 124 may transmit or receive data via antenna B 128. Communication device 110 may utilize multiple input / multiple output ("MIMO") communication techniques to communicate using multiple transceivers across a network channel. The network channel may represent a communication channel within a radio frequency band. For example, the network channels may include 802.11a, 802.11b, 802.11g, 802.11n, or 802.11ac, Worldwide Interoperability for Microwave Access ("WiMAX"), Bluetooth, HSPA + ≪ / RTI > 4G, 3GPP LTE, and others.

The wireless communication radio 120 may use time multiplexing techniques and additionally use multiple input / multiple output (MIMO) techniques to transmit and receive data across the two network channels. For example, at time tl, the wireless communication radio 120 uses both transceiver A 122 for driving antenna A 126 and transceiver B 124 for driving antenna B 128 And transmits data over the first network channel CH1. At a later time t2, the wireless communication radio 120 again transmits data over the second network channel CH2, using both transceiver A 122 and transceiver B 124. [ The wireless communication radio 120 continues to alternate between transmitting data over the first network channel and transmitting data over the second network channel, as shown further at times t3 and t4 It can be repeated. At any point in time, all communication resources (e.g., transceiver A 122 and transceiver B 124) associated with wireless radio 120 are capable of communicating over a single network channel Lt; / RTI > The time multiplexed communication method 100 may also be called as a single band communication because the communication device 110 communicates over a single network channel at any point in time.

2 illustrates a timing example 200 of simultaneous multi-band communication. The communication device 210 may include a wireless communication radio 220. The wireless communication radio 220 may transmit and receive data in accordance with a wireless communication standard, such as any of the communication standards listed previously. The wireless communication radio 220 may also include multiple transceivers, such as transceiver A 222 and transceiver B 224 in this example. Transceiver A 222 and transceiver B 224 may each include an antenna, such as antenna A 226 and antenna B 228, respectively, through which the transceiver may transmit or receive data. Alternatively, the wireless communication radio 220 may include a plurality of transmitters used for transmitting data and a plurality of receivers for receiving data. For example, the communication device 210 may include an M x N MIMO communication radio, including M number of transmitters and N number of receivers. A transmitter, receiver, or transceiver may be implemented in the physical ("PHY") portion of the wireless communication device 210 or in the PHY core.

In operation, the wireless communication radio 220 may use transceiver A 222 and transceiver B 224 to transmit data over a single network channel, such as CH1. For purposes of illustration, at time tl, the wireless communication radio 220 may transmit data across the network channel CHl using both transceiver A 222 and transceiver B 224. In a similar manner, wireless communication radio 220 may receive data over network channel CH1 using transceiver A 222 and transceiver B 224. When communicating over the network channel CH1, the communication device 210 may communicate with the first device 240, for example, via the first wireless network 230. [

The communication device 210 and the wireless communication radio 220 may also communicate over multiple network channels at the same time. As an example, at time t2, the wireless communication radio 220 operates in a simultaneous multi-band communication mode.

At time t2, the communication device 210 may recognize the switch indication 290 on the wireless communication radio 220 based on a request to communicate over the second network channel, such as the network channel CH2 . The switching indication (e.g., toggle indication 290) may be a message indicating a change in the communication mode, which is transmitted from the controller or system logic in the communication device 210 to the transceivers. Optionally, the indicia 290 can specify which transceiver to use to communicate across the communication network. Alternatively, the switching indication may be a message sent from the network controller to the device 210 or a message from devices attempting to connect to the communication device 210 (e.g., the second device 250). The device can send a switch indication to the transceivers for various reasons. For example, the communication device 210 may send a switching indication to the transceivers upon expiration of a timer configured by the system logic at the device 210 or from other devices. The communication device 210 or other devices may also recognize or transmit a switching indication based on communication parameters, security parameters, power usage parameters, and the like. Also, changes to the device in which the communications device 210 or the communications device 210 are communicatively coupled may be a system logic < RTI ID = 0.0 > certificate, < / RTI >

The request to communicate over the network channel CH2 may arise from a diverting state comprising as an operation on the communication device 210, as an operation on the second device 250, or as an operation elsewhere. For example, an application executing on the communication device 210 may request that data be transmitted via the second wireless network 232. [ As another example, the second device 250 may transmit data to the communication device 210 using the network channel (CH2) of the second wireless network 232, and the communication device 210 may transmit data to the network channel RTI ID = 0.0 > CH2) < / RTI > The communication device 210 may be capable of switching to a simultaneous multi-band communication mode in any environment in which the communication device 210 can communicate with multiple devices across multiple networks or across multiple network connections. have. The communication device 210 may determine which transceiver (s) to assign to the network connection based on various factors, such as data throughput requirements, service quality, signal conditions, security requirements, power management, . Also, the communication device 210 may switch to the simultaneous multi-band communication mode whenever the communication device 210 is in time-division communication (e.g., single-band communication as described in FIG. 1).

To support simultaneous multi-band communication, the communication device 210 may allocate resources of the wireless communication radio 220 to simultaneously communicate over the network channel CH1 and the network channel CH2. For example, communication device 210 may assign transceiver A 222 to communicate over network channel CH 1 and transceiver B 224 to communicate across network channel (s) CH 2. Thus, at time t2, communication device 210 may simultaneously communicate data across multiple network channels (e.g., over network channels CH1, CH2). The wireless radio 220 may use the transceiver A 222 to communicate with the first device 240 over the network channel CHl through the first wireless network 230. [ At the same time wireless radio 220 may use transceiver B 224 to communicate with second device 250 over network channel CH2 via second wireless network 232.

When communicating simultaneously across multiple network channels, the communication device 210 may simultaneously receive data from multiple networks (e.g., the first wireless network 230 and the second wireless network 232) . For example, the communication device 210 may receive these beacon messages from both the first wireless network 230 and the second wireless network 232, even though the access point ("AP ") beacon messages overlap the reception time . Similarly, when operating in the simultaneous multi-band communication mode, the communication device 210 may broadcast packets to both the first wireless network 230 and the second wireless network 240 even when the packet transmission time overlaps. can do. In addition, when operating in the simultaneous multi-band communication mode, the communication device 210 reduces the overhead required to continue to switch communication resources for subsequent communication over one network channel while operating in a single- .

3 shows another timing example 300 of simultaneous multi-band communication. As previously described, communication device 210 may include wireless communication radio 210 including transceiver A 222 and transceiver B 224. Transceiver A 222 may include antenna A 226 and transceiver B 224 may comprise antenna B 228. From time tl to time t4, the communication device 210 may communicate over the first network channel CHl and the second network channel CH2 in a single band communication mode. (E.g., transceiver A 222 and transceiver B 224) associated with wireless radio 220 at any point in time while communication device 210 is operating in a single band communication mode. May be used to communicate across a single network channel. At time tl, the communication device 210 may communicate over the network channel CH1 using both transceiver A 222 and transceiver B 224 (e.g., to transmit data or receive data do). As shown in FIG. 2, the communication device 210 may communicate with the first device 240 over the network channel CH1 and through the first wireless network 230. As shown in FIG.

At time t2, the communication device 210 can continue to communicate in a single-band communication mode. However, at time t2, the communication device 210 may stop communicating over the network channel CH1 and instead instruct the wireless radio 220 to communicate over the network channel CH2. In response, the wireless radio 220 may instead redirect communication resources associated with the wireless radio 220 to communicate across the network channel CH2. Thus at time t2 wireless radio 220 may use transceiver A 222 and transceiver B 224 to communicate over the network channel CH2 and over the second wireless network 232. [ In this way, the communication device 210 can communicate with the second device 250, for example. At time t3, the communication device 210 may resume communication over the network channel CH1 while continuing to operate in a single-band communication mode.

At time t4, the wireless radio 220 may receive a switch indication 390 from the system logic of the communication device 210 to switch the operation to the multi-band communication mode. As discussed above, the communication device 210 may allocate resources from the wireless radio 220 to support communication in a multi-band communication mode. 3, the communication device 210 allocates transceiver B 224 to be used for communicating with the first device 240 across the network channel CH1 and over the first wireless network 230 . The communication device 210 may also allocate transceiver A 222 to be used to communicate with the second device 250 over the network channel CH2 and over the second wireless network 232. [ The allocation of communication resources by the communication device 210 may be implemented as system logic, as described in more detail below.

Because communication device 210 and wireless radio 220 have previously operated in a single band communication mode prior to receiving switch indication 390, communication device 210 may be able to communicate with additional resources . For example, when communicating in a single band communication mode, the communication device 210 may use a single medium access control ("MAC") related architecture and a set of MAC related resources to support communications over a single network channel . To support operating in a multi-band communication mode, the communication device 210 may replicate communication resources such as a MAC related architecture. For purposes of illustration, communication device 210 may assign previously used MAC related resources in a single-band communication mode used for transceiver B to communicate over network channel CH1. Next, the communication device 210 may replicate some MAC-related architectures used for the transceiver A 222 to communicate over the network channel (CH2). Cloning of the MAC-related architecture can be implemented in software. Details of specific MAC-related elements for replication associated with the multi-band communication mode are shown in FIG. 7 and discussed in more detail below.

After communication device 210 has allocated the communication resources of wireless radio 220 and replicated any additional MAC related architectures, communication device 210 may communicate with different wireless networks using a single radio and with different network channels The first device 240 and the second device 250 can communicate simultaneously. This simultaneous multi-band communication is illustrated in Fig. 3 going forward from time t4.

4 shows a timing example 400 of simultaneous multi-band communication. The communication device 410 shown in FIG. 4 includes a wireless communication radio 420. Wireless communication radio 420 includes three transceivers: transceiver A 422, transceiver B 424, and transceiver C 426. Transceiver A includes antenna A 427, transceiver B includes antenna B 428, and transceiver C 426 includes antenna C 429. The communication device 410 may operate in a single band communication mode and various multi-band communication modes.

At time tl, the communication device 410 and the wireless communication radio 420 may operate in a multi-band communication mode in which each of the three transceivers simultaneously communicates over a respective single network channel. That is, at time tl, the communication device 410 may use the transceiver A 422 to communicate with the first device 440 over the network channel CHl and through the first wireless network 430 . At the same time, transceiver B 424 may be used to communicate with the second network device 450 across the network channel (CH2) and through the second wireless network 432. Similarly, transceiver C 426 may be used to simultaneously communicate with third network device 460 over network channel CH3 and over third wireless network 434. [

At time t2, the wireless radio 420 may receive the switching indication 490 to operate differently (or alternatively, in a different multi-band communication mode) in the multi-band communication mode. For example, a communication or communication session with the second device 450 may include communication resources associated with communications over the network channel CH2 (e.g., transceiver B 424) for another use at time t2 You can complete freeing. Accordingly, communication device 410 may assign transceiver B 424 to be used with transceiver C 426 to communicate over network channel CH3. The wireless communication radio 420 may continue to use transceiver A 426 to communicate across the network channel CHl.

At time t2, the communication device 410 may stop communicating over the network channel CH2. As such, communication resources previously associated with communicating over the network channel CH2 from before time t2 may be deallocated by the communication device 410. [ For example, a replicated MAC-related architecture associated with transceiver B 424 and used to communicate across network channel (CH2) prior to time t2 may be deallocated by the system logic of communication device 410 .

At time t3, the wireless communication radio 420 may instead receive a toggle indication 491 to operate in a different multi-band mode by communicating over the network channels CH2 and CH3. As such, the communication device 410 allocates transceiver C 426 to communicate across the network channel CH 2 and allocates transceiver A 422 and transceiver B 424 to communicate across the network channel CH 1 can do. The communication device 410 may also deallocate previously used MAC related architectures for communication across the network CH3. The communication device 410 may further replicate a MAC-related architecture for use in communicating over the network channel (CH2). Alternatively, the communication device 410 may use a MAC-related architecture that is used at time t3 in time t2 to communicate across the network channel CH3 for use in communicating over the network channel CH2 after t3 You can switch. At time t3, the communication device 410 can communicate simultaneously over the network channels CH1 and CH2.

At time t4, the wireless communication radio 420 may receive the switching indication 492 to operate in a single band communication mode. Thus, the replicated additional MAC architecture used to support concurrent multi-band communication can be deallocated. The communication device 410 is then able to communicate with a single network channel CH1, such as the network channel CH2 at time t4, the network channel CH3 at time t5, and the network channel CH1 at time t6, Lt; / RTI > All of the three transceivers are connected to the wireless radio 220 for communication over the network channel CH2 at time t4, the network channel CH3 at time t5, and the network channel CHl at time t6. Lt; / RTI >

5 illustrates an example of a mobile communication device 510 supporting simultaneous multi-band communication. The communication device 510 includes a communication interface 520. The communication interface 520 may include a plurality of radios, such as the radio 522 and the radio 524 shown in FIG. Each radio of the communication device 510 may be operable to communicate according to a communication type or standard. For example, the radio 522 may be a WiFi radio, a cellular radio, a Bluetooth radio, or any other type of wireless communication radio. Radio 522 and radio 524 may be configured to communicate according to different communication types or standards. As an example, the radio 522 may be a WiFi radio and the radio 524 may be a Bluetooth radio.

Each radio (e.g., radio 522 and radio 524) of communication device 510 may include multiple PHY cores. The radio 524 includes a PHY core 532, a PHY core 534, a PHY core 536, and a PHY core 538. The PHY core may include a transmitter, a receiver, or both (e.g., a transceiver). A PHY core that includes a transceiver may be referred to as a PHY transceiver core. The PHY cores 532, 534, 536 and 538 may each be a PHY transceiver core comprising a transceiver. PHY cores 532, 534, 536, and 538 may also include register space. Portions of the register space may be used to track the current communication mode of the PHY core. Portions of the register space may also be used to track the network channels currently allocated or assigned for communication by the PHY core.

The communication device 510 shown in FIG. 5 also includes system logic 540 that is communicatively coupled to the communication interface 520. The system logic 540 may be implemented in hardware, software, or both, such as with a processor 550 (or multiple processors) and a memory 560 communicatively coupled to the processor 550. The memory 560 may be implemented by a processor 550 to enable communication devices to communicate in a single-band communication mode or various simultaneous multi-band communication modes, such as the communication modes described in Figures 1-4, Instructions 562 may be stored. The memory 560 may also store a MAC related architecture 564 (e.g., a packet queue or a security engine) that may be replicated in association with the simultaneous multi-band communication mode.

In operation, the system logic 540 may configure the radio, such as the radio 514, to communicate over a single network channel or to simultaneously communicate across multiple network channels. The system logic 540 may control the communication mode of the radio 524, for example, by sending a switch indication to the radio 524 that may change the communication mode of the radio 524. [ The system logic 540 may also allocate communication resources associated with the radio 524 used in the communication mode. For example, in the simultaneous multi-band communication mode, the system logic 540 may allocate a PHY core 532 for use in communicating over a first network channel, and at the same time, 534, 536, and 538, respectively. The system logic 540 may update the respective register space of each of the PHY cores 532, 534, 536 and 538 to reflect the updated communication mode and each assigned network channel. Specifically, the system logic 540 may update the register space of the PHY caller 532 to indicate the updated communications mode of the radio 524 and the particular network channel to which the PHY core 532 is assigned to communicate . System logic 540 may update the respective register spaces of PHY cores 534, 536, and 538 in a similar manner.

As another example, the system logic 540 may communicate with the PHY core 532 to communicate over the first network channel, the PHY core 534 to communicate over the second network channel, The PHY core 536, and the PHY core 538 to communicate over the fourth network channel. PHY cores 532, 534, 536, and 538 may simultaneously transmit or receive data across each of the assigned network channels. In this example, system logic 540 comprises radio 524 to operate as essentially four single-input-single-output ("SISO") systems. In other words, the system logic 540 may maintain one connection for each PHY core in the radio 524, four separate network connections via the radio 524. [ Along the same lines, the system logic 540 can support up to a maximum of M network connections in the radio including M number of PHY transceiver cores. Similarly, the system logic 540 may support up to a maximum of M network connections in an M x M communication radio including M transmitters and M transmitters. System logic 540 may control the communication mode of other radios of communication device 510, such as radio 522, in a similar manner.

When the system logic 540 changes the communication mode of the radio of the communication device 510, existing communication parameters for communicating with the network device may be varied. For example, at a first point in time tl, the radio 524 may communicate with the PHY cores 532, 534 (e. G., The first device 240) , 536, and 538) to communicate in a single band communication mode. At a later point in time t2, the system logic 540 sends a switch indication to the radio 524 to communicate simultaneously with the second device (e.g., the second device 250) over the second network channel . To support this simultaneous multi-band communication mode, the system logic 540 allocates PHY cores 532 and 534 to continue to communicate with the first device over the first network channel, PHY cores 536 and 538 may be assigned to communicate with the device.

In this example, the communication parameters for communicating with the first device will change at time t2 when the radio 524 switches to the simultaneous multi-band communication mode. That is, at time t2, the wireless radio 524 will switch from communicating with the first device using the four PHY transceiver cores to communicating with the first device using the two PHY transceiver cores. In this regard, the system logic 540 may send a display message over the first network channel to a first device that indicates a change in communication parameters. The display message may indicate to the first device that the communications device 510 is now to transmit data to the first device using the two PHY transceiver cores, specifically the PHY cores 532 and 534. Similarly, the indication message may indicate that the communication device 510 is now to receive data from the first device using two PHY transceiver cores, which means that the first device communicates data to the communication device 510 It can affect the way. The system logic 540 may send a similar indication message to the affected device whenever the communication parameters with the device are changed (e.g., when the radio of the communication device 510 changes the communication mode).

6 illustrates an example of a simultaneous multi-band logic 600 that may be implemented in hardware, software, or both. The simultaneous multi-band instructions 562 may implement logic 600, for example. Simultaneous multiband logic 600 may describe how system logic 540 and radio 524 transition from operating in a single-band communication mode to operating in a multi-band communication mode.

System logic 540 may instruct radio 524 to communicate over a single network channel using multiple PHY transceiver cores such as PHY cores 532, 534, 536 and 538 (602). The radio 524 may operate in a single band communication mode in which the PHY cores 532, 534, 536 and 538 of the radio 524 communicate over a single network channel. The radio 524 may also operate in a single band communication mode in which the PHY cores 532, 534, 536 and 538 of the radio 524 communicate over multiple network channels in a time division manner PHY cores 532-538 communicate over a single network channel at a given time point).

The system logic 540 may identify the switch state based on the communications device 510 task or other task (604). The switched state may be any situation that guarantees the transition to the simultaneous multi-band communication mode. For example, the switching state may occur based on an operation from a communication device or an operation from a device over which the communication device 510 communicates over a first network channel. If no transition state is identified, the radio 524 may continue to communicate over the first network channel in a single band communication mode. The divert state can ensure radio 524 to switch the communication mode to communicate over the additional network channel.

Once the switch state is identified, the system logic 540 may send a switch indication to the radio 524 (606). The switch indication may instruct radio 524 to operate in the simultaneous multi-band communication mode. The system logic 540 may then allocate 608 the communication resources of the radio 524 to continue communicating over the first network channel. For example, system logic 540 may allocate a first set of PHY transceiver cores of radio 524 for use in communicating over a first network channel. System logic 540 may assign 610 the communications of radio 524 to communicate over a second network channel, such as a second set of PHY transceiver cores of radio 524. Similarly, the system logic 540 may allocate communication resources to communicate over additional network channel (s) as indicated by the divert state.

Next, the system logic 540 may replicate additional MAC related architectures to support the simultaneous multi-band communication mode (612). A set or example of an additional MAC-related architecture may be replicated for each additional network connection or each additional network channel through which the radio 524 will communicate. Examples of additional MAC-related architectures that are replicated by the system logic 540 may be stored in the memory 560 of the communication device 510. Certain additional MAC related architectures that the system logic 540 may duplicate are further described below.

When replicating an additional MAC-related architecture, the system logic 540 may send a display message (614). The display message may be transmitted to a device communicatively coupled to the communication device 510 via the first network channel. As described above, the indication message may indicate a change in communication parameters in communication with the device, such as a change in communication resources allocated to the radio 524 for use in communicating with the device. The radio 524 may operate in simultaneous multi-band mode (616) by simultaneously communicating over multiple network channels.

System logic 540 may then identify (618) a switch state that may guarantee switching to a single-band communication mode or a simultaneous different multi-band communication mode. System logic 540 may determine to switch to a single band communication mode based on the switched state. In such a case, the system logic 540 may deallocate (620) the MAC related architecture used to support the simultaneous multi-band communication mode. System logic 540 may then send 622 a switch indication to radio 520, which may direct radio 520 to operate in a single-band communication mode. The radio 520 may then communicate 602 in a single band communication mode.

System logic 540 may alternatively determine to switch to a different band communication mode based on the switched state. For example, the switched state may include a situation where the communication device 510 stops or completes communication with another device, which may eliminate the need to communicate over a network channel. To further illustrate, the radio may support four simultaneous network connections, and when identifying a switch state, the system logic 540 may instead decide to switch to communicate over three network connections simultaneously. As another example, the switching may include system logic 540 that receives requests from another device to communicate over the new network channel, which may also be used by the system logic 540 in a different simultaneous multi-band communication mode To communicate with each other.

Depending on the transition state, the system logic 540 may deallocate the MAC-related architecture, such as when the system logic 540 switches to a simultaneous multi-band communication mode to support fewer network connections (624 ). The system logic 540 may then be ready to communicate across the new simultaneous multi-band communication mode in a similar manner as described above (606 through 616). In particular, the system logic 540 may replicate the MAC-related architecture 612 to support communication across additional network connections. System logic 540 may relinquish to duplicate the MAC-related architecture when it is specified that the new simultaneous multi-band communication mode or switch indication communicates over fewer network connections than before.

The system logic 540 may be used to determine whether a stationary state is identified, such as when the communication device 510 does not support network communications or enters an idle or power saving mode in which it is powered off, Communication in one of the multi-band communication modes may be stopped (626). Powering off communications device 510 may be accomplished by, for example, reducing substantially one or more operating voltage (s) by removing or disconnecting one or more operating voltage (s) normally applied to the processor core, . ≪ / RTI >

FIG. 7 illustrates an example of a MAC-related architecture 700, a portion of which may be replicated to support simultaneous multi-band communication. The MAC related architecture 700 may be part of the MAC architecture used by the communication device 510 to simultaneously span the first network channel A and the second network channel B. [ The MAC-related architecture 700 includes a host processor interface 702 that can interface with other portions of the communication device 510. The MAC related architecture 700 also includes a PHY interface 704 that can interface with the wireless PHY layer. For example, the wireless PHY layer can be composed of a digital PHY, an analog PHY, and a physical radio.

The MAC related architecture 700 shown in FIG. 7 also includes a host processor 710 that includes a transmitter A 710 and a receiver A 712 that may be used to communicate over a first network connection over a first network channel (A) Interface 702 and the PHY interface 704. The PHY interface 702 includes a data path, The MAC related architecture 700 also includes a transmitter B 714 and a receiver B 716 that may be used to simultaneously communicate over a second network connection over a second network channel B. [

The MAC related architecture 700 also includes security engine A 720 and security engine B 722. In operation, security engine A 720 may receive data from a transmit first-in-first-out ("FIFO") queue A 730. The security engine (e.g., security engine A 720 or security engine B 722) may be a Wired Equivalent Policy (WEP), Temporal Key Integrity Protocol (TKIP), an Advanced Encryption Standard (AEC) And may support a number of security standards such as CCMP (CBC-MAC Protocol) based on any other security algorithm. Security engine A 720 can encrypt the data received from TX-FIFO A 730 and then communicate the encrypted data to transmitter A 710. Security engine A 720 may also receive encrypted data from receiver A 712, decrypt the received data, and forward decrypted data to receive FIFO queue A 732. The MAC-related architecture 700 may also be used in connection with communicating over the second network channel B similarly.

The MAC related architecture 700 also includes a transmit ("FIFO") queue A 730 and a receive FIFO queue B 732 that can be used to communicate over the first network channel A. Transmit FIFO queue A 730 may receive data from device interface 702 to be transmitted over first network channel A, which may be communicated to WEP engine A 730 for encryption in a first-in, first-out manner. Receive FIFO queue A 730 may receive decoded data from WEP engine A. [ Data from receive FIFO queue A 732 may be transmitted via device interface 702 in a first-in, first-out manner. A similar transmit FIFO queue B 734 and receive FIFO queue B 736 are included in the MAC related architecture 700 that may be used in conjunction with communicating over the second network channel B. [

The MAC related architecture 700 includes a Power Management Queue (PMQ) A 750, a PMQ B 752, an Interframe Space (IFS) A 760, an IFS B 762 A time synchronization function ("TSF ") timer A 770, a TSF timer B 772, a network allocation vector A (NAV) A 780 and a NAV B 782 , Which may be used to communicate over network channel A and network channel B, respectively.

The MAC related architecture also includes a programmable state machine ("PSM ") 790 that can handle time critical tasks such as transmission and reception processing of packet sequences . The MAC related architecture 700 also includes an internal hardware register ("IHR ") 792 that can provide access to hardware control and context information.

Portions of the MAC-related architecture 700 may be replicated by the system logic 540 to support operating the radio in a simultaneous multi-band communication mode. One set of MAC related resources may be allocated for use in communicating over each individual network connection or channel to which the communication resources of the radio are assigned. The MAC-related resources used by the communication device 510 to support the simultaneous multi-band communication mode of the radio may include any combination of elements of the MAC-related architecture 700 shown in FIG. When an additional MAC-related architecture is requested in association with the multi-band communication mode, the system logic 540 may replicate additional MAC-related architectures for use in simultaneous multi-band communications, for example, in memory. Similarly, when the radio changes communication modes such that no additional MAC related architectures are required, the system logic 540 can deallocate any such additional MAC related architectures.

The above-described methods, devices, and logic may be implemented in many different ways in many different combinations of hardware, software, or both hardware and software. For example, all or part of the system may comprise a controller, a microprocessor, or an application specific integrated circuit (ASIC), or may be implemented on a single integrated circuit or distributed among multiple integrated circuits Discrete logic or components, or any other type of analog or digital circuitry. All or part of the above-described logic may be implemented as instructions for execution by a processor, controller, or other processing device and may be implemented in flash memory, random access memory (RAM), or read only memory ), Erasable and non-volatile machine readable or computer readable media such as erasable programmable read only memory (EPROM) or compact disk read only memory (CDROM) Memory, or other machine-readable medium such as a magnetic or optical disk. Accordingly, an article, such as a computer program product, can include a storage medium and computer readable instructions stored on the medium, which, when executed at an end point, cause the computer system or other device To perform operations according to any of the above.

The processing capabilities of the system may be distributed among a number of system components, such as multiple processors and memories, optionally including multiple distribution processing systems. The parameters, databases, and other data structures can be stored and managed individually, integrated into a single memory or database, logically and physically organized in many different ways , Data structures such as linked lists, hash tables, or implicit storage mechanisms, which may be implemented in many ways. Programs may be distributed across multiple memories and processors or may be distributed over a single program implemented in many different ways, such as in a library such as a shared library (e.g., a Dynamic Link Library (DLL) (E. G., Subroutines). ≪ / RTI > For example, a DLL may store code that performs any of the above-described system processes. While various embodiments of the present invention have been described, it will be apparent to those skilled in the art that many more embodiments and implementations are possible within the scope of the present invention. Accordingly, the invention is not limited except as to the appended claims and equivalents thereof.

Claims (15)

1. A method of a multiple-input-multiple-output ("MIMO") communication device including a wireless radio having a plurality of physical ("PHY") transceiver cores,
Alternately communicating in time division fashion across a first network channel and a second network channel using the plurality of PHY transceiver cores together;
Recognizing a transition indication to operate in a simultaneous multi-band communication mode,
In response:
Assigning a first PHY transceiver core from the plurality of PHY transceiver cores to communicate over the first network channel;
Assigning a second PHY transceiver core from the plurality of PHY transceiver cores to communicate over the second network channel; And
Communicating data over the first network channel using the first PHY transceiver core while simultaneously communicating data over the second network channel using the second PHY transceiver core. The method according to claim 1,
Wherein the first PHY transceiver core is different than the second PHY transceiver core. The method according to claim 1,
Further comprising identifying a switching state to switch operation in a simultaneous operation mode. The method according to claim 1,
Wherein the first set of PHY transceiver cores include a single PHY transceiver core and the second set of PHY transceiver cores include a single PHY transceiver core. The method according to claim 1,
Receiving a switching indication to operate in a single band communication mode; And
Further comprising communicating data over a network channel using the plurality of PHY transceiver cores. The method according to claim 1,
Further comprising replicating a medium access control ("MAC") related architecture to support communicating data across the plurality of network channels. delete A first PHY core operable to communicate across multiple network channels;
A second PHY core operable to communicate across multiple network channels; And
A communications controller communicatively coupled to the first PHY core and the second PHY core, the communications controller comprising:
A single-band communication mode in which the first PHY core and the second PHY communicate data over a network channel in a time division manner; And
And a multi-band communication mode in which the first PHY core communicates data over a first network channel while the second PHY core communicates data over a second network channel. The communication controller being operable to set a current communication mode of the second PHY. The method of claim 8,
Wherein the first network channel and the second network channel are associated with different network connections. The method of claim 9,
Wherein the first PHY core includes a register space that tracks the current communication mode of the first PHY core. The method of claim 8,
And the second PHY core includes a register space that tracks the current communication mode of the second PHY core. The method of claim 8,
Wherein the multi-band communication mode comprises a medium access control ("MAC") related architecture that is replicated to support both the first and second PHY cores. delete The method of claim 12,
The MAC related architecture may include a data path between a host processor interface and a PHY interface, a direct-memory-access ("DMA") channel, an encryption engine, a time synchronization function timer, a first- And a combination thereof. 1. A method in a multiple-input-multiple-output ("MIMO") communication device comprising a plurality of physical (&
Performing MIMO communication over a first network channel associated with a first network connection using the plurality of PHY cores;
Receiving a request to communicate across a second network connection;
Allocating a first subset of the plurality of PHY cores to continue communication over the first network channel;
Assigning a second subset of the plurality of PHY cores to communicate over a second network channel associated with the second network connection, wherein the second subset of the plurality of PHY cores comprises a plurality of PHY cores Assigning a second subset of the plurality of PHY cores that does not include any PHY cores from the first subset; And
Communicating over the first network channel using the first subset of the plurality of PHY cores and communicating over the second network channel using the second subset of the plurality of PHY cores How to.

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